TY - JOUR
T1 - Global analysis of heat transfer considering three-dimensional unsteady melt flow in CZ crystal growth of oxide
AU - Jing, C. J.
AU - Ihara, S.
AU - Sugioka, K. I.
AU - Tsukada, T.
AU - Kobayashi, M.
AU - Mito, M.
AU - Yokoyama, C.
N1 - Funding Information:
The authors would like to express their sincere thanks to the staff member of the Center for Computational Materials Science of the Institute for Materials Research, Tohoku University, for their continuous support in the use of the SR8000 supercomputing facilities. The present work was partly supported by Casio Science Promotion Foundation. In addition, project 50576079 partly supported by NSFC.
PY - 2007/9/1
Y1 - 2007/9/1
N2 - The conventional global model of heat transfer for the Czochralski (CZ) crystal growth of oxides is based on a pseudo-steady axisymmetric assumption. However, because oxide melt flow is commonly three-dimensional and unsteady, an approach to formulate a global model in which a three-dimensional unsteady melt flow is taken into account was proposed in this study. This approach couples a conventional global model of heat transfer and a model of a three-dimensional, unsteady melt flow using two interface models. The newly developed global model was validated and used to investigate the effect of a three-dimensional, unsteady melt flow on oxide crystal growth. The results indicate that the effect of a three-dimensional, unsteady melt flow is too large to be neglected when the crystal rotational Reynolds number is relatively large. It was found that a three-dimensional, unsteady melt flow shifts the critical Reynolds number at which interface inversion occurs at a much lower value than that obtained using a conventional model based on a pseudo-steady axisymmetric assumption.
AB - The conventional global model of heat transfer for the Czochralski (CZ) crystal growth of oxides is based on a pseudo-steady axisymmetric assumption. However, because oxide melt flow is commonly three-dimensional and unsteady, an approach to formulate a global model in which a three-dimensional unsteady melt flow is taken into account was proposed in this study. This approach couples a conventional global model of heat transfer and a model of a three-dimensional, unsteady melt flow using two interface models. The newly developed global model was validated and used to investigate the effect of a three-dimensional, unsteady melt flow on oxide crystal growth. The results indicate that the effect of a three-dimensional, unsteady melt flow is too large to be neglected when the crystal rotational Reynolds number is relatively large. It was found that a three-dimensional, unsteady melt flow shifts the critical Reynolds number at which interface inversion occurs at a much lower value than that obtained using a conventional model based on a pseudo-steady axisymmetric assumption.
KW - A1. Global analysis of heat transfer
KW - A1. Interface inversion
KW - A1. Internal radiative heat transfer
KW - A2. Czochralski method
KW - B1. Oxide
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U2 - 10.1016/j.jcrysgro.2007.06.012
DO - 10.1016/j.jcrysgro.2007.06.012
M3 - Article
AN - SCOPUS:34548130814
SN - 0022-0248
VL - 307
SP - 235
EP - 244
JO - Journal of Crystal Growth
JF - Journal of Crystal Growth
IS - 1
ER -